†, https://orcid.org/0000-0003-0990-3428
Received: July 28, 2020; Revised: September 8, 2020; Accepted: September 21, 2020
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408 Oxford Medical Case Reports, 2020;11,408–410
doi: 10.1093/omcr/omaa103 Case Report
C A S E R E P O R T
Use of injectable collagen in partial-thickness tears
of the supraspinatus tendon: a case report
Bruno Corrado
1,
*
,†
, Ilenia Bonini
1
, Vincenzo Alessio Chirico
1
,
Nicola Rosano
2
and Pietro Gisonni
2
1
Department of Public Health, University Federico II of Naples, 80131 Naples, Italy,
2Department of Advanced
Biomedical Sciences, University Federico II of Naples, 80131 Naples, Italy
*Correspondence address: Department of Public Health, University Federico II of Naples, Italy, Via S. Pansini n.5, 80131 Naples, Italy. Tel:+390817462796; Fax:+390817462881; E-mail: bruno.corrado@unina.it
Abstract
Management of partial-thickness rotator cuff tears is actually controversial. We treated a patient with a partial-thickness tear of the supraspinatus tendon by a series of four type I porcine collagen ultrasound-guided injections, at weekly intervals. At the same time the patient underwent physical therapy, consisting of motor re-education and proprioceptive exercises. The patient was assessed before the treatment and up to 18 months after the last injection by the Constant–Murley score, the Disability of Arm, Shoulder and Hand questionnaire and ultrasonography. Shoulder pain and functional limitation progressively improved and they almost completely disappeared at the last follow-up. Ultrasonography showed a gradual healing of the partial-thickness tear and a regeneration of the tendon structure. This is the first study on ultrasound-guided injections of type I porcine collagen for the treatment of partial-thickness rotator cuff tears. Future research should confirm the excellent result achieved in this case report.
INTRODUCTION
Partial-thickness rotator cuff tear (PTRCT) is one of the most common shoulder injuries [1]. The supraspinatus (SSP) tendon is the most affected in PTRCTs [1]. The treatment of PTRCTs remains disputed; non-operative treatment is the first approach [2]. Many injectable therapies have been proposed in the last years with controversial effectiveness [3]. According to literature, this is the first study on ultrasound (US)-guided injections of type I porcine collagen for the treatment of PTRCTs.
CASE REPORT
In March 2018, a 55-year-old right-handed housewife came to the Physical Medicine and Rehabilitation Practice complaining of pain and functional limitation in the left shoulder, lasting 2 months. She didn’t report neither systemic or genetic disorders, nor previous traumas or surgical interventions and nor allergies or intolerances. She suffered from hypothyroidism
and she was in treatment with sodium levothyroxine. She didn’t smoke. She was habitually practising free-body gymnastics twice a week. She had already treated the shoulder pain with rest, non-steroidal anti-inflammatory drugs and physical therapy, without improvements.
Based on physical examination we suspected left SSP tendon involvement. We excluded glenohumeral osteoarthritis by X-rays. Shoulder ultrasonography, performed by a radiologist with
>20 years of experience in skeletal muscle US, revealed a partial-thickness tear of the articular surface of the SSP tendon (Grade II according to Ellman classification). We decided to treat the patient with a series of four US-guided intratendineous injec-tions of 2-ml porcine type I collagen at weekly intervals in combi-nation with physical therapy. After a full and clear description of the study, the patient was invited to sign the informed consent. Injections were performed by a single doctor with >10 years of experience using an anterior approach. The patient was seated on a chair with the arm in internal rotation in order to expose as much of the SSP tendon as possible. This position was
Use of injectable collagen in partial rotator cuff tears 409
Table 1: CM score and DASH questionnaire values
T0 T1 T2 T3 T4 CM score 47 52 77 84 97 DASH score 57 48 36 34 4
Figure 1: Outcome measures of the CM score and the DASH questionnaire over
the time.
best achieved by placing the patient’s arm behind her back. A 22-gauge needle was directed towards the tear of the SSP tendon as guided by US until the tip of the needle was seen in the correct position and then the collagen was injected slowly.
Physiokinesitherapy was performed starting from the first injection and during 4 weeks, three times a week, 30 minutes per session and consisted of motor re-education and proprioceptive exercises, with the aim to recover range of motion and strength of the shoulder.
The patient was evaluated at the time of enrolment (T0), right before the third injection (T1), and 1 month (T2), 3 months (T3) and 18 months (T4) after the last injection by means of the Con-stant–Murley (CM) score and the Disability of the Arm, Shoulder and Hand (DASH) questionnaire. Clinical data are reported in
Table 1and their trends illustrated inFigure 1.
US assessment was performed at T0, T3 and T4 by the same expert radiologist. As shown inFig. 2, longitudinal US of the SSP tendon at T0 showed a well-defined hypoechoic area, indicating partial-thickness tear of the articular surface of the tendon, without retraction (Grade II according to Ellman classification). Three months following the last injection, the partial-thickness tear became smaller and less defined (Grade I according to Ell-man classification). Eventually, the T4 US assessment no longer showed tear within the tendon, which in addition appeared quite regular and isoechoic.
Figure 2: US assessment of the SSP tendon across multiple follow-up intervals. (a)
Longitudinal US of the SSP tendon at T0 showed a well-defined partial-thickness tear of the articular surface of the tendon, without retraction (arrow). (b) Three months following the last injection, the partial-thickness tear became smaller and less defined (arrow). (c) At 18-month follow-up, the tendon looked quite regular and isoechoic, without any sign of tear (arrow).
The patient was totally compliant, following all the appoint-ments given. No adverse events have been described after colla-gen injections.
DISCUSSION
According to literature, the diagnostic sensitivity and specificity of shoulder US on rotator cuff tear detection has a range of 46–95% and 50–95%, respectively [4]. The variability is highly correlated with the level of experience of the operator and the patterns of the rotator cuff tears [4].
Non-operative treatment is the first approach to PTRCTs, and surgical option has to be considered when the conservative treatment has not effect within the first 6–12 weeks [2]. Physical therapy is the first-line treatment [5]. Rest from exacerbating activity, especially repetitive overhead activity and heavy lifting, can improve the pain component. Cortisone injections may be helpful in alleviating pain in conjunction with physical therapy but offer only short-term effects [3].
410 B. Corrado et al.
Different injectable therapies have been proposed in the past years for the treatment of PRTCTs (e.g. hyaluronic acid, platelet-rich plasma, prolotherapy), but they have achieved controversial effectiveness according to literature [3].
We have decided to treat the PTRCT of our patient with type I collagen injections on the base of (i) the positive effect proved by injectable collagen on the tendon structure of cultured tenocytes [6]; (ii) the good results achieved by collagen patches implanted arthroscopically in the treatment of large and massive RC tears [7] and (iii) the promising outcomes of collagen injections in the treatment of epicondylitis and SSP tendinopathy without tears [8,9]. Studies of degenerative tendons have found a small but significant decrease in the total collagen content and an increased proportion of collagen type III relative to collagen type I. The increase in the collagen type III to collagen type I ratio was consistent with smaller, less organized and weaker tendons.
This case report has one main limitation: the patient was not previously treated with other injective therapies; so, we cannot state that the positive effect on the PTRCT is certainly due to type I porcine collagen only. It is well known indeed that tendon needling is able to disrupt the chronic degenerative process of tendinopathies favouring localized bleeding and fibroblastic pro-liferation [10]. However, no data exist on the benefits of tendon needling as a stand-alone treatment for tendon tears.
In conclusion, the tear healing, the improvement in the ten-don structure, the clinical and functional positive outcomes and the absence of side effects allow us to propose collagen injections as a valid option for the treatment of PTRCTs. A regenerative effect of collagen injections on tendon structure may be assumed to account the results achieved. More studies are needed to confirm these findings.
CONFLICT OF INTEREST STATEMENT
None declared.
ETHICAL APPROVAL
No approval was required.
CONSENT
An informed patient consent has been completed and it is held by the treating institution.
GUARANTOR
Bruno Corrado.
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